Graph coloring

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A 3-coloring suits this graph, but fewer colors would result in adjacent vertices of the same color.  Finding the minimum number of colors for an arbitrary graph is NP-hard.
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A 3-coloring suits this graph, but fewer colors would result in adjacent vertices of the same color. Finding the minimum number of colors for an arbitrary graph is NP-hard.

In graph theory, graph coloring is an assignment of "colors", (red, blue and so on, but consecutive integers starting from 1 can be used without loss of generality), to certain objects in a graph. Such objects can be vertices, edges, faces, or a mixture of those.

Vertex coloring is the most important kind. It is the starting point of the entire subject, and other coloring problems can be transformed into a vertex version. For example, an edge coloring of a graph is just the vertex coloring of its line graph. Likewise, a face coloring of a planar graph is just the vertex coloring of its (planar) dual. However, to keep things in their perspective, non-vertex coloring problems are usually stated and studied as are.

Graph coloring is not to be confused with graph labeling, which is an assignment of labels, usually also in the form of numbers, to vertices or edges. In graph coloring problems, colors (e.g. 1, 2, 3...) are nothing more than markers for keeping track of adjacency or incidence. In graph labeling problems, labels (e.g. 1, 2, 3...) are calculable values that need to satisfy a certain numerical condition in the definition of the labeling.

Graph coloring enjoys many practical applications as well as theoretical challenges. Beside the classical types of problems, different limitations can also be set on the graph, or on the way a color is assigned, or even on the color itself. It has even reached popularity with the general public in the form of the popular number puzzle Sudoku. Graph coloring is still a very active field of research.

Note: Many terms used in this article are defined in the glossary of graph theory.

Contents

[edit] Vertex coloring

When used without any qualification, a coloring of a graph is always assumed to be a vertex coloring, namely an assignment of colors to the vertices of the graph. Again, when used without any qualification, a coloring is nearly always assumed to be proper, meaning no two adjacent vertices are assigned the same color. Here, "adjacent" means sharing the same edge. A coloring using at most k colors is called a (proper) k-coloring and is equivalent to the problem of partitioning the vertex set into k or fewer independent sets. The problem of coloring a graph has found a number of applications such as scheduling, register allocation in compilers, frequency assignment in Mobile radios, and pattern matching.

[edit] Chromatic number

The least number of colors needed to color the graph is called its chromatic number χ. For example the chromatic number of a complete graph Kn of n vertices (a graph with an edge between every two vertices), is χ(Kn) = n. A graph that can be assigned a (proper) k-coloring is k-colorable, and it is k-chromatic if its chromatic number is exactly k.

The problem of finding a minimum coloring of a graph is NP-hard. The corresponding decision problem (is there a coloring which uses at most k colors?) is NP-complete, and in fact was one of Karp's 21 NP-complete problems. It remains NP-complete even on planar graphs of degree at most 4, as shown by Garey and Johnson in 1974, although on planar graphs it's trivial for k ≠ 3 (due to the four color theorem). There are however some efficient approximation algorithms that employ semidefinite programming.

Some properties of χ(G):

  1. χ(G) = 1 if and only if G is totally disconnected.
  2. χ(G) ≥ 3 if and only if G has an odd cycle (equivalently, if G is not bipartite).
  3. χ(G) ≥ ω(G).
  4. χ(G) ≤ Δ(G)+1.
  5. χ(G) ≤ Δ(G) unless G is a complete graph or an odd cycle (Brooks' theorem).
  6. χ(G) ≤ 4, for any planar graph G. This famous result, called the four-color theorem, was stated by P. J. Heawood in 1890 (first written reference by Augustus De Morgan in 1852), but remained unproven until 1976, when it was established by Kenneth Appel and Wolfgang Haken at the University of Illinois at Urbana-Champaign.

Here Δ(G) is the maximum degree, and ω(G), the clique number.

About infinite graphs, much less is known. The following is one of the few results about infinite graph coloring:

If all finite subgraphs of an infinite graph G are k-colorable, then so is G. (de Bruijn, Erdős 1951)

[edit] Chromatic polynomial

This graph can be 3-coloured in 12 different ways.
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This graph can be 3-coloured in 12 different ways.

The chromatic polynomial counts the number of ways a graph can be coloured using no more than a given number of colours. For example, using three colours, the graph in the image to the right can be coloured in 12 ways. With only two colours, it cannot be coloured at all. With four colours, it can be coloured in 24 + 4⋅12 = 72 ways: using all four colours, there are 4! = 24 valid colourings (every assignment of four colors to any 4-vertex graph is a proper coloring); and for every choice of three of the four colours, there are 12 valid 3-colourings. So, for the graph in the example, a table of the number of valid colourings would start like this:

Available colors 1 2 3 4
Number of colorings 0 0 12 72

The chromatic polynomial is a function P(G,t) that counts the number of t-colorings of G. As the name indicates, for a given G the function is indeed a polynomial in t. For the example graph, P(G,t) = t(t − 1)2(t − 2), and indeed P(G,4) = 72.

The chromatic polynomial includes at least as much information about the colorability of G as does the chromatic number. Indeed, χ is the smallest positive integer that is not a root of the chromatic polynomial,

χ(G) = min{k:P(G,k) > 0}

It was first used by Birkhoff and Lewis in their attack on the four-color theorem. It remains an unsolved problem to characterize graphs which have the same chromatic polynomial and to determine precisely what polynomials are chromatic.

[edit] Examples

The Petersen graph has chromatic number 3.
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The Petersen graph has chromatic number 3.
Chromatic polynomials for certain graphs
Triangle K3 t(t − 1)(t − 2)
Complete graph Kn t(t − 1)(t − 2)...(tn + 1)
Tree with n vertices t(t − 1)n − 1
Cycle Cn (t − 1)n + ( − 1)n(t − 1)
Petersen graph t(t − 1)(t − 2)(t7 − 12t6 + 67t5 − 230t4 + 529t3 − 814t2 + 775t − 352)

[edit] Properties

  • P(G,0) = 0
  • P(G,1) = 0 if G contains an edge
  • P(G,t) = 0, if t < χ(G).
  • P(G, − 1) is the number of acyclic orientations of G[1]
  • If G has n vertices, m edges, and k components G1,G2,…,Gk, then
    • P(G,t) has degree n.
    • The coefficient of tn in P(G,t) is 1.
    • The coefficient of tn − 1 in P(G,t) is m.
    • The coefficients of t0,t1,tk − 1 are all zero.
    • The coefficient of tk is nonzero.
    • P(G,t) = P(G1,t)P(G2,t)P(Gk,t)
  • The coefficients of every chromatic polynomial alternate in signs.
  • A graph G with n vertices is a tree if and only P(G,t) = t(t − 1)n − 1.
  • The derivative evaluated at unity, P'(G,1) is the chromatic invariant θ(G) up to sign

[edit] Computing the chromatic polynomial

Whenever G contains a loop, it cannot be legally colored at all, so

P(G,t) = 0.

If e not a loop, then the chromatic polynomial satisifes the recurrence relation

P(G,t) = P(Ge,t) − P(G / e,t),

where Ge is the graph with the edge removed, and G / e is the graph with the edge's endpoints contracted into a single vertex.

The two expressions give raise to a recursive procedure, called the deletion–contraction algorithm. In the recursive step, the instance is transformed into two instances that are at least one edge smaller, so the running time comes within a polynomial factor of 2m, where m is the number of edges. The analysis can be improved to 1.62n + m.

Other algorithms are known, but all are exponential in the size of the graph. For some classes of graphs, polynomial-time algorithms are known. These include the empty and complete graphs, forests, chordal graphs, wheels, and ladders. In general, computing the chromatic polynomial is Sharp-P-complete, so it is unlikely that a polynomial time algorithm for all graphs will be found.

[edit] List of other colorings

Not only can the idea of vertex coloring be extended to edges, but also be added with different conditions to form new structures and problems.

  • edge coloring - edges are colored
  • list coloring - each vertex chooses from a list of colors
  • list edge-coloring - each edge chooses from a list of colors
  • total coloring - vertices and edges are colored
  • harmonious coloring - every pair of colors appears on at most one edge
  • complete coloring - every pair of colors appears on at least one edge
  • exact coloring - every pair of colors appears on exactly one edge
  • acyclic coloring - every 2-chromatic subgraph is acyclic
  • strong coloring - every color appears in every partition of equal size exactly once
  • on-line coloring - the instance of the problem is not given in advance and its successive parts become known over time
  • equitable coloring - the sizes of color classes differ by at most one
  • sum-coloring - the criterion of minimalization is the sum of colors
  • T-coloring - distance between two colors of adjacent vertices must not belong to fixed set T
  • rank coloring - if two vertices have the same color i, then every path between them contain a vertex with color greater than i.
  • interval edge-coloring - a color of edges meeting in a common vertex must be contiguous.
  • circular coloring - motivated by task systems in which production proceeds in a cyclic way
  • path coloring - models a routing problem in graphs
  • fractional coloring - vertices may have multiple colors, and on each edge the sum of the color parts of each vertex is not greater than one

Some improper colorings:

  • cocoloring -- every color class induces an independent set or a clique
  • subcoloring -- every color class induces a union of cliques

[edit] References

  1. ^ Stanley, 1973

[edit] Literature

  • R. L. Brooks: On colouring the nodes of a network. In: Proc. Cambridge Phil. Soc. 37, 1941, 194–197.
  • N. G. de Bruijn, P. Erdős: A colour problem for infinite graphs and a problem in the theory of relations. In: Nederl. Akad. Wetensch. Proc. Ser. A 54, 1951 371–373. (Indag. Math. 13.)
  • Tommy R. Jensen, Bjarne Toft: Graph coloring problems. Wiley-Interscience, New York 1995 ISBN 0-471-02865-7.
  • Marek Kubale and others: Graph Colorings. American Mathematical Society 2004 ISBN 0-8218-3458-4.
  • M. R. Garey, D. S. Johnson, and L. Stockmeyer. Some simplified NP-complete problems. Proceedings of the sixth annual ACM symposium on Theory of computing, p.47-63. 1974.
  • Michael R. Garey and David S. Johnson (1979). Computers and Intractability: A Guide to the Theory of NP-Completeness. W.H. Freeman. ISBN 0-7167-1045-5. A1.1: GT4, pg.191.

[edit] See also

[edit] External links

  • Graph Coloring Page by Joseph Culberson (graph coloring programs)
  • CoLoRaTiOn by Jim Andrews and Mike Fellows is a graph coloring puzzle
  • GF-Graph Coloring Program [1]